KR960002834B1 - How to set up optimal call of wireless private exchange device - Google Patents

Abstract

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Description

How to set up optimal call of wireless private exchange device

1 is a block diagram of a conventional wireless private exchange device.

2 is a state transition diagram for explaining a method for setting an optimal call of a wireless private switching device according to the present invention.

3 is a flow chart of operation in the dashed state shown in FIG.

4 is a flow chart of operation in the level-2 standby state shown in FIG.

5 is a flow chart of operation in the level-3 standby state shown in FIG.

6 is a flow chart of the operation in the guard state shown in FIG.

* Explanation of symbols for main parts of the drawings

1: Main controller 2 ₁ ~ 2 _n : Fixed device

3 ₁ ~ 3 _n : Portable device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless private exchange device, and more particularly, to set an optimal call path by selecting a message having the largest signal level among the signal levels of messages received by a main controller through a plurality of fixed devices from one portable device. The present invention relates to a method for setting an optimal currency of a private exchange device.

In general, the wireless private switching device, which is a mobile communication system that implements a mobile communication service in a small area, has a main controller 1, a plurality of fixed devices 2 ₁ to 2 _n , and a plurality of portable devices as shown in FIG. Device 3 ₁ to 3 _n . The fixed devices 2 ₁ to 2 _n detect a signal received through the wireless channel from the portable devices 3 ₁ to 3 _n and output the signal to the main controller 1 through a wire, and wire the wire from the main controller 1. Outputs the signal supplied through the wireless channel to the portable device (3 ₁ ~ 3 _n ) side. The main controller ₁ implements a mobile communication service by analyzing and processing a message supplied from each fixed device 2 ₁ to 2 _n through a wire. In this case, the radio signals communicated between the fixing devices 2 ₁ to 2 _n and the portable devices 3 ₁ to 3 _n may be distinguished in two types. That is, a broadcast is directed toward a plurality of fixed devices 2 ₁ to 2 _n from one portable device before the radio channel is established between the fixed devices 2 ₁ to 2 _n and the portable devices 3 ₁ to 3 _n . -Type messages and non-broadcast messages that select and fix radio channels between fixed devices 2 ₁ and 2 _n and portable devices 3 ₁ and 3 _n so that messages can be sent and received through already established channels. have. When the mobile device fires an outgoing request message to make an outgoing call, the outgoing request message can be received by all adjacent fixed devices (2 ₁ to 2 _n ). After that, the fixing devices 2 ₁ to 2 _n transmit the received message to the main controller 1 through a wired path. At this time, the main controller 1 receives a message having the same meaning from a plurality of fixing devices (2 ₁ ~ 2 _n ). In this way, since the main controller ₁ receives a plurality of identical messages from each of the fixed devices 2 ₁ to 2 _n , the main controller ₁ receives the operating software of the general switching apparatus that receives and processes one message in one state. Not applicable to In the case of using a call processing method for only one message, the message fired from the portable device 3 ₁ to 3 _n is received when the mobile device 3 ₁ to 2 _n is received at each adjacent fixing device 2 ₁ to 2 _n . 3 _n ) and the fixing device (2 ₁ ~ 2 _n ) has a problem that is greatly affected by the distance. In addition, when such a method is applied, the message that arrives first because the time required for the message communicated in each fixing device 2 ₁ to 2 _n to be delivered to the main controller 1 is not the same. The call processing algorithm has a problem in that call processing software that implements a mobile communication service such as a wireless private switching device cannot select an optimal call path and thus deteriorates the call quality due to an unstable state of the call path.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and it is possible to set an optimal call path by selecting a message having the largest signal level among the signal levels of messages received from a portable device through a plurality of fixed devices. It is an object of the present invention to provide a method for setting an optimal translation of a wireless private exchange.

In order to achieve the above object, the present invention provides a first step in which a main control device receives a plurality of messages supplied through a plurality of fixed devices from a portable device for a plurality of delay times, and after the first step, the main control device receives them. A second step of dividing the electric field strength of a plurality of messages in multiple stages according to a plurality of reference values and using a message having the largest electric field strength among the plurality of received messages; and after this second step, the main controller And a third step of setting a call path to allow the portable device to communicate with the fixed device which has sent the greatest intensity message.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention uses a variable delay technique to set the optimal currency path. The messages fired by the portable devices 3 ₁ to 3 _n are received by a plurality of fixed devices 2 ₁ to 2 _n in the adjacent position, and several messages having the same meaning arrive at the main control unit 1 side. At this time, each message includes electric field strength indicating the state of the channel according to the distance and environment between the portable device and each fixed device, and data about the fixed device number assigned to each fixed device. The main controller (1) is a mobile device (3 ₁ ~ 3 _n) and the retainer (2 ₁ ~ 2 _n) according to electric field intensity data of the message supplied by the variable delay technique from the fixed device (2 ₁ ~ 2 _n) Only one stationary device (2 ₁ to 2 _n ) having the optimal radio channel status is selected and delivered to the call processor. In other words, the variable delay technique divides the electric field strength into multiple levels according to the reference level, and assigns a different delay time for each reference time, so that a message with a large field strength is processed quickly, while a message with a low electric field strength has a fixed processing time. It is a method of selecting a message having a high field strength that arrives late by delaying time. Using this method, the messages are not processed in the order of message arrival according to the distance between the fixing devices 2 ₁ to 2 _n and the main controller 1 and the processing time, but in the order of the magnitude of the electric field. By processing the message, it is possible to select a fixture having an optimum electric field strength. In addition, after the fixing device is selected in this manner, a guard time is given for a predetermined time to filter out duplicate messages arriving from other fixing devices to prevent duplicate processing by these messages.

As shown in FIG. 2, an optimal call path setting process of the main controller 1 using the variable delay technique is performed. If the electric field strength of the message arriving from the fixing device in the standby state 10 is greater than the level-1 value (the largest electric field strength reference value), the message is transmitted to the call processor and then the guard state 12 goes to the standby state ( If the electric field strength of the message arrived from the fixing device in step 10) is greater than the level-2 value (the second largest electric field strength reference value), it goes to the level-2 standby state (11), and arrives from the fixing device in the waiting state (10). If the electric field strength of the message is greater than the level-3 value (third large electric field strength reference value), the state goes to the level-3 waiting state 13. If the electric field strength of the message arriving from the fixing device in the level-2 waiting state 11 is less than the level-1 value, the level-2 waiting state 11 is maintained, and the fixing device in the level-2 waiting state 11 If the field strength of the message arriving from the message is greater than the level-1 value or a level-2 timeout occurs, then the guard state 12 is reached. If the electric field strength of a message arriving from the fixing device in the level-3 waiting state 13 is less than the level-1 value, the level-3 waiting state 13 is maintained, and the fixing device in the level-3 waiting state 13 If the electric field strength of the message arriving from is greater than the level-1 value or a level-3 timeout occurs, the state goes to the guard state 12. In the guard state 12, the same message arriving from the fixing device is ignored until the guard timeout occurs, so that duplicate processing for the same message does not occur. If the guard timeout occurs in the guard state 12, the standby waits. Go to state 10.

In the standby state 10 of FIG. 2, the main controller 1 operates in the order shown in FIG. 3. In the standby state (step 31), when a message is received from the fixing device, the electric field strength of the received message is measured (step 32), and it is determined whether the electric field strength is greater than the level-1 value (step 33). If the electric field strength is greater than the level-1 value in step 33, the message is sent to the call processor (step 34), the guard timer is driven (step 35), the guard state is entered (step 36), and the operation ends. (Step 44). If the electric field strength is smaller than the level-1 value in step 33, it is determined whether the electric field strength is larger than the level-2 value (step 37). If the electric field strength is greater than the level-2 value in step 37, the received message is written to the buffer (step 38), the level-2 waiting timer is started (step 39), and the level-2 standby state is entered. The operation ends (step 40) (step 44). If the electric field strength is less than the level-2 value in step 37, the received message is written to the buffer (step 41), the level-3 waiting timer is started (step 42), and the level-3 waiting state is entered (step 42). 43) The operation ends (step 44).

In the level-2 standby state 11 of FIG. 2, the main controller 1 operates in the order shown in FIG. In the level-2 waiting state (step 50), it is determined whether the level-2 waiting timer has timed out (step 51). If the level-2 wait timer has not timed out in step 51, it is determined whether the electric field strength of the message arriving from the fixed device is greater than the level-1 value (step 52). If the electric field strength is greater than the level-1 value in step 52, the operation of the level-2 wait timer is stopped (step 53), the arrived message is sent to the call processor (step 54), and the guard timer is driven (step 54). 55) After entering the guard state (step 56), the operation ends (step 62). In step 52, if the electric field strength is smaller than the level-1 value, it is determined whether the electric field strength is larger than the previously arrived message (step 57), and if the electric field strength is smaller than the previously arrived message, the operation is terminated (step 62) If the electric field strength is larger than the previously arrived message, the received message is written to the buffer (step 58) and the operation is terminated (step 62). If the level-2 wait timer has timed out in step 51, the message written to the buffer is regarded as an optimal message and is transmitted to the call processor (step 59), the guard timer is driven (step 60), and the guard state is entered. After that (step 61), the operation ends (step 62).

In FIG. 2, in the level-3 standby state 13, the main control unit 1 operates in the order shown in FIG. 5. In the level-3 standby state (step 70), has the level-3 wait timer timed out? (Step 71). If the level-3 wait timer has not timed out in step 71, it is determined whether the electric field strength of the message received from the fixed device is greater than the level-1 value (step 72). If the electric field strength is greater than the level-1 value in step 72, the operation of the level-3 wait timer is stopped (step 73), the arrival message is sent to the call processor (step 74), and the guard timer is driven (step 75). After entering the guard state (step 76), the operation ends (step 89). If the electric field strength is smaller than the level-1 value in step 72, it is determined whether the electric field strength of the received message is greater than the level-2 value (step 77). In step 77, if the electric field strength is greater than the level-2 value, it is determined whether the remaining timer time is longer than the level-2 waiting timer time (step 78). After the message has been written to the buffer (step 83), the operation ends (step 89). If the remaining timer time is longer than the level-2 wait timer time, the operation of the level-3 wait timer is stopped (step 79). Is written to the buffer (step 80), the level-2 wait timer is driven (step 81), the system enters the level-2 wait state (step 82), and the operation ends (step 89). If the field strength of the message received in step 77 is less than the level-2 value, it is determined whether the field strength is greater than the previously arrived message (step 84), and if the field strength is smaller than the previously arrived message, the operation is performed. If the electric field strength is larger than that of the previously arrived message (step 89), the received message is written to the buffer (step 85), and the operation is terminated (step 89). If the level-3 wait timer has timed out in step 71, the message written to the buffer is regarded as an optimal message and transmitted to the call processor (step 86), the guard timer is activated (step 87), and the guard state is entered. Subsequently (step 88), the operation ends (step 89).

In guard state 12 of FIG. 2, main controller 1 operates in the order shown in FIG. In the guard state (step 91), it is determined whether the guard timer has timed out (step 92). If the guard timer has not timed out in step 92, it is determined whether the message received from the fixed device is the same as the previously received message (step 93), and if the received message is different from the previously received message, it is treated like a waiting state. After that (Step 94), the operation ends (Step 97). If the received message is the same as the previously received message, the received message is ignored and the message having the same meaning is prevented from being delivered to the call processor (Step 95). The operation ends (step 97). If the guard timer has timed out in step 92, the operation enters the standby state (step 96) and ends the operation (step 97).

As described above, according to the present invention, when a message fired from a portable device is received through adjacent fixing devices and delivered to a main controller, the fixing device is arranged in order according to a corresponding message reception time of each fixing device and a distance from the main controller. Selecting a fixed device in the optimal position according to the electric field strength value indicating the state of the radio channel without selecting, and a message having the same meaning when the message released from the portable device is supplied to the main controller through the multiple fixed devices When multiple arrivals, the guard state can be prevented from overlapping the same message, it is possible to set the optimal call path between the portable device and the fixed device.

Claims (2)

A wireless private switching device, comprising: a first step in which a main control device receives a plurality of messages supplied from a portable device through a plurality of fixed devices for a plurality of delay times, after which the main control device receives a plurality of messages received by the main control device; A second step of dividing the electric field strength into multiple stages according to a plurality of reference values and processing a call using a message having the largest electric field strength among a plurality of received messages; and after this second stage, the main controller has the largest electric field strength. And a third step of setting a communication path for the fixed device to which the message has been sent and the portable device can make a call. The apparatus of claim 1, wherein the message supplied from the long-term portable device to the main controller through the plurality of fixed devices includes electric field strength information, fixed device identification information, and portable device identification information. How to set the currency.